KR102027895B1 - Voltex type gas-liquid mixing scrubber apparatus using vaccum - Google Patents

Abstract

The present invention relates to a vortex type gas-liquid mixing scrubber apparatus using vacuum pressure comprising a plurality of impact plates and nozzles so that gas ascends and descends from a gas inlet of a scrubber housing to an outlet. After absorption liquid is filled to the height of the nozzle, vacuum pressure is applied from the outlet direction of the scrubber housing. The vortex of the absorption liquid and gas in the scrubber housing is formed to improve a scrubbing effect.

Description

Vortex-type gas-liquid mixing scrubber device using vacuum pressure {VOLTEX TYPE GAS-LIQUID MIXING SCRUBBER APPARATUS USING VACCUM}

The present invention relates to a vortex-type gas-liquid mixed scrubber device using a vacuum pressure, and more particularly, in the gas-liquid mixed scrubber device, the gas is raised and lowered and moved in a direction from the gas inlet to the outlet of the scrubber housing. A plurality of impingement plates and nozzles are provided, and the absorbent liquid is filled to the height position of the nozzle, and then a vacuum pressure is applied in the direction of the outlet of the scrubber housing, thereby forming a vortex of the absorbent liquid and the gas inside the scrubber housing to improve the scrubbing effect. The present invention relates to a vortex type gas-liquid mixed scrubber apparatus using vacuum pressure that can be used.

The present invention efficiently removes gaseous substances such as SOx, NOx, HCl, volatile organic compounds (VOCs), and odors contained in exhaust gases emitted from various industrial facilities such as power plants, steel mills, and incinerators, and particulate matter such as fine dust and heavy metals. The present invention relates to a scrubber apparatus for simultaneously processing.

Scrubbers are commonly called wet dust collectors, which clean the gas impregnated by droplets, liquid films, and bubbles, adhere to the particles, promote coagulation between the particles, and separate particles from direct gas flow. In addition, the water-soluble odor removal efficiency and high economical compared to other odor removal methods are widely used in industrial processes to remove odors and dust in the gas phase.

As the types of scrubbers, packed tower scrubbers, spray tower scrubbers, venturi scrubbers, ejector scrubbers, and single column scrubbers are used. In the conventional scrubber methods, in order to increase the gas-liquid mixing rate and increase the particle removal efficiency in the gas, the absorbing liquid is sprayed. I was using the way.

This spraying method of absorbent liquid has a great effect of separating odors and particles in the gas by increasing the contact ratio between the gas supplied into the scrubber and the absorbent liquid, but requires a facility such as a spray nozzle for spraying the absorbent liquid evenly. There is a need for a technique for controlling the injection of the absorbent liquid such as the injection pressure, and there is also a problem in that maintenance costs are generated due to the absorbent liquid injection facilities such as clogging of the nozzle.

As described above, the present invention utilizes the vacuum pressure and structural features of the impingement plate and the nozzle inside the scrubber device to supply the absorbent liquid and the scrubber device filled in the scrubber device without using a method of spraying the absorbent liquid. The present invention aims to present a technique for a new scrubber device in which vortices are effectively mixed while forming vortices, resulting in excellent gas odor and particle separation effects.

Next, the prior art existing in the field to which the technology of the present invention belongs will be briefly described, and then the technical matters to be made differently from the prior art will be described.

First, Korean Patent Publication No. 10-1055592 (2011.08.08.) Relates to a water wall rotary polluted air purifying apparatus, and more specifically, the harmful gas is introduced and purified by chemical reaction and washing of the harmful gas. A scrubber through which the purified gas is discharged; A blowing unit for sucking the harmful gas and introducing the same into the scrubber; The reaction liquid is injected into the scrubber and the reaction liquid is injected into the scrubber to form a pressure and introduce the pressure back into the scrubber. The scrubber rotates in the same direction when the harmful gas is introduced into the reaction liquid. A reaction part in which a chemical reaction and washing are performed by collision reaction up and down using an inner cylinder jaw installed in the upper and lower parts; An upper discharge part installed at an upper end of the reaction part to remove moisture contained in the gas and having a purge gas discharge port formed at an uppermost end thereof; A technology related to a water wall rotary polluted air purifying device, which is installed at a lower end of the reaction part and stores a reaction liquid reacting with the harmful gas, is stored in the lower part storing the cleaned dust and the material generated by reacting with the harmful gas. It is.

In addition, Japanese Patent No. 6345466 (2015.11.09.) Relates to a scrubber type deodorizing apparatus, and more specifically, an introduction unit for introducing a target gas into a malodor capture liquid, the target gas and the malodor capture liquid, A gas-liquid mixing unit for mixing the gas-liquid to remove malodors in the gas to be treated, a liquid supply port for supplying the malodor trapping liquid, and a liquid discharge unit for discharging and discharging the malodor capturing liquid capturing the malodor. The gas for discharging the to-be-processed gas from which the malodor has been removed is provided between the gas-liquid mixing portion and the liquid discharge portion, provided with a partition wall that blocks the space above the malodor capture liquid in the liquid discharge portion and the gas-liquid mixing portion. The apparatus which concerns on the scrubber system deodorizing apparatus provided in the part which forms the space through which an outlet port passes above the said gas-liquid mixing part. This has been described.

Patent Documents No. 10-1055592 and Japanese Patent No. 6345466 are provided with a collision plate or inner cylinder inside a scrubber device, and the gas flowing into the scrubber device swings up and down along the collision plate or inner cylinder. Although there are some similarities to the present invention in that it is mixed with the absorbent liquid inside the scrubber device, the absorbent liquid filled inside the scrubber device by the vacuum pressure, the impingement plate and the structure of the nozzle formed by the impingement plate as in the present invention. As a vortex is formed, a technique for enhancing the gas-liquid mixing effect is not included.

In addition, Patent Publication No. 10-1827121 (December 8, 2017 publication date) relates to a high efficiency multi-stage vortex type wet scrubber, and more specifically, after installing two separate chambers, nozzles located in each chamber A technique is described for a scrubber which generates a strong vortex of the cleaning liquid by increasing the number of collisions and contacts between the cleaning liquid and the air pollutants and increases the contact area.

The prior art document No. 10-1827121 is similar to the present invention in that it is a technique of increasing the contact ratio between the cleaning liquid and the air pollutants by generating a vortex of the cleaning liquid by using a nozzle, but the nozzle as in the present invention In addition, the structural features of the impingement plate does not include a technique for maximizing the vortex generation of the absorbent liquid, there was still a problem using the method of spraying the absorbent liquid.

The present invention has been made to solve the above problems, and in the gas-liquid mixing scrubber device for supplying gas into the scrubber device filled with the absorbent liquid to separate the odor and particles in the gas, the impingement plate and the nozzle inside the scrubber device By using the structural feature of the absorbent liquid, the absorbent liquid charged inside the scrubber apparatus and the gas supplied into the scrubber apparatus form a vortex while improving the gas-liquid contact efficiency, thereby eliminating odors and particles in the gas. It is an object of the present invention to provide a vortex type gas-liquid mixed scrubber device that can be improved.

In addition, the present invention, in the vortex-type gas-liquid mixing scrubber device as described above, by applying a vacuum pressure in the direction of the gas outlet, to increase the gas flow rate inside the scrubber device, to lower the pressure in the space filled with the absorbent liquid, An object of the present invention is to provide a vortex-type gas-liquid mixed scrubber device using a vacuum pressure to form a bubbling of gas and gas.

In the vortex type gas-liquid mixed scrubber device using a vacuum pressure according to an embodiment of the present invention, a gas inlet is formed at a side surface, a gas discharge part is formed at an upper surface thereof, and a cylindrical shape in which an absorbent liquid is filled to a predetermined height. A scrubber housing having an inner space; A gas-liquid vortex mixing unit which is provided inside the scrubber housing and in which the gas flowing from the gas inlet unit forms a vortex with the absorbent liquid and is mixed; A mist removing unit positioned in an upper direction of the gas-liquid vortex mixing unit in the scrubber housing and absorbing mist in the gas passing through the gas-liquid vortex mixing unit; And a vacuum pump provided in a direction of the gas discharge part of the scrubber housing to lower the pressure inside the gas-liquid vortex mixing part and to increase the moving speed of the gas by applying a vacuum pressure to the inside of the scrubber housing. The gas-liquid vortex mixing unit includes: a first horizontal collision plate configured to extend in a horizontal direction from an inner surface of the scrubber housing in a direction in which the gas inlet is formed at a position higher than the gas inlet; It is installed in a vertical direction so as to be spaced apart and parallel to the inner surface of the scrubber housing in which the gas inlet is formed, the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, the upper end is the first A first vertical collision plate configured to be connected to the horizontal collision plate; A first nozzle formed in the first vertical impingement plate and having an opening shape protruding in a lateral direction opposite to a side at which the gas inlet is located, wherein an upper end of the opening is formed to match the filling height of the absorbent liquid; The first vertical collision plate is installed in the vertical direction so as to be spaced apart at a predetermined interval in parallel to the side of the side opposite the side where the gas inlet is located, the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, A second vertical impingement plate configured to have a distal end connected to the first horizontal impingement plate; A second nozzle formed in the second vertical impingement plate and having an opening shape protruding in a lateral direction opposite to a side at which the first vertical impingement plate is located, wherein a lower end of the opening is formed to fit the filling height of the absorbent liquid; It is installed in the vertical direction so as to be spaced apart and parallel to the second vertical collision plate at a predetermined interval, and the lower end is spaced at a predetermined interval from the filling height of the absorbent liquid, the predetermined length from the lower end at a predetermined angle A third vertical collision plate having a shape inclined toward a second vertical collision plate, and having an upper end connected to an end of the first horizontal collision plate; Located between the first vertical collision plate and the second vertical collision plate, spaced apart from the first vertical collision plate and the second vertical collision plate at a predetermined interval and installed in the vertical direction, the upper end is the first horizontal collision Spaced apart from the plate at a predetermined interval, and the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, and the upper and lower portions each have an inclined shape in the direction of the first vertical collision plate at a predetermined angle. A first inclined collision plate configured to have a bottom height position of the first nozzle; Located between the second vertical collision plate and the third vertical collision plate, spaced apart from the second vertical collision plate and the third vertical collision plate at a predetermined interval and installed in the vertical direction, the upper end is the first horizontal collision Spaced apart from the plate at a predetermined interval, and the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, and the upper and lower portions each have an inclined shape in the direction of the second vertical collision plate at a predetermined angle. A second inclined collision plate configured to have a lower end height position of the second nozzle; And extending laterally from an inner surface of the scrubber housing in a direction in which the first horizontal collision plate is not formed at a position higher than the first horizontal collision plate, wherein a predetermined length is extended at a predetermined angle from the extended end. And a second horizontal collision plate configured to be inclined downward.

In addition, as an embodiment, the vortex-type gas-liquid mixing scrubber apparatus using the vacuum pressure, it characterized in that it comprises a water level controller for adjusting the level of the absorbent liquid in accordance with the filling height of the predetermined absorbent liquid.

In addition, as an embodiment, the scrubber housing, characterized in that it comprises a; heater for heating the internal absorption liquid.

In addition, as an embodiment, the first inclined collision plate, based on the boundary between the upper and lower, the upper portion has a form inclined toward the first vertical collision plate at an angle of 70 to 80 degrees, the lower portion 110 It characterized in that it has a form inclined in the direction of the first vertical impingement plate at an angle of 120 to 120 degrees.

In addition, as an embodiment, the second inclined collision plate, based on the boundary between the upper and lower, the upper portion has a form inclined toward the second vertical collision plate at an angle of 70 to 80 degrees, the lower portion 110 It characterized in that it has a form inclined in the direction of the second vertical impingement plate at an angle of 120 degrees.

In addition, as an embodiment, the first inclined collision plate or the second inclined collision plate is characterized in that the angle between the upper and lower boundary portion is configured to have an obtuse angle.

In an embodiment, the opening of the first nozzle or the second nozzle may be inclined toward the lower surface of the scrubber housing at an angle of 270 degrees based on the water surface of the absorbent liquid.

In addition, the third vertical collision plate, characterized in that the predetermined length from the lower end is inclined in the direction of the second collision plate at an angle of 0 to 120 degrees relative to the water surface of the absorbent liquid.

In addition, as an embodiment, the second horizontal collision plate, the predetermined length from the extended end so as to be inclined through the bent portion in the downward direction over the secondary, the angle of the bent portion is 120 to 160 degrees It is characterized by having.

In addition, as an embodiment, the gas inlet is a gas inlet flow rate range of 6,000 to 12,000m ³ / hr, the first nozzle or the second nozzle is characterized in that the diameter of the opening is 8 to 10mm.

In addition, as an embodiment, positioned between the first inclined collision plate and the first vertical collision plate, and spaced apart adjacent to the first inclined collision plate at a predetermined interval, the upper portion relative to the center of the first And a first vortex amplifying plate extending in a predetermined length in parallel with the inclined collision plate and having a lower portion concave rounded in the direction of the first vertical collision plate.

In addition, as an embodiment, the second inclined collision plate and the second vertical collision plate, located between the second inclined collision plate and spaced apart at a predetermined interval, the upper portion relative to the center of the second And a second vortex amplifying plate extending in a predetermined length in parallel with the inclined collision plate and having a lower portion concave rounded in the direction of the second vertical collision plate.

In addition, as an embodiment, the vacuum pump, characterized in that to apply a vacuum pressure of 250 to 400mmAq inside the scrubber housing.

In the vortex-type gas-liquid mixed scrubber apparatus using the vacuum pressure according to the present invention, by forming a vortex mixed with the absorbent liquid while the gas passes through the absorption plate and the nozzle in the scrubber housing by the vacuum pressure applied in the direction of the gas discharge portion of the scrubber housing. In addition, there is an effect that can have a high gas odor and particle separation effect without using a method of spraying the absorbent liquid.

In addition, the vortex type gas-liquid mixed scrubber device using the vacuum pressure according to the present invention increases the gas flow rate inside the scrubber device by lowering the pressure in the space filled with the absorbent liquid by applying a vacuum pressure in the direction of the gas outlet. The bubbling of the absorbent liquid and gas can easily occur to improve the odor and particle separation effect in the gas.

In addition, the present invention forms a vortex of the absorbent liquid by using the vacuum pressure, the impingement plate and the nozzle as described above to generate bubbling mixed with the gas and the absorbent liquid, without the absorbent liquid injection nozzle and its peripheral device that the conventional scrubber device has Sufficient scrubbing effect can be obtained, which can save the cost of facility construction and maintenance.

1 is a schematic cross-sectional view of a vortex type gas-liquid mixed scrubber device using a vacuum pressure according to an embodiment of the present invention.
Figure 2 is a schematic cross-sectional view of the vortex-type gas-liquid mixing scrubber apparatus using a vacuum pressure according to another embodiment of the present invention.
Figure 3 is a schematic cross-sectional view for explaining the movement of the gas in the vortex-type gas-liquid mixing scrubber apparatus using a vacuum pressure according to an embodiment of the present invention.

In the drawings of the present invention, the size or dimensions of the structures are shown to be enlarged or reduced than actual for clarity of the present invention, and well-known configuration is omitted to show the characteristic configuration is not limited to the drawings. .

In describing the principles of the preferred embodiment of the present invention in detail, if it is determined that the detailed description of the related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In addition, the configuration shown in the embodiments and drawings described herein is only one of the most preferred embodiment of the present invention and does not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Throughout this specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding the other components unless otherwise stated.

The present invention relates to a vortex-type gas-liquid mixing scrubber device using a vacuum pressure, and more particularly, has a plurality of impingement plates and nozzles provided to move the gas up, down and away from the gas inlet to the outlet of the scrubber housing. And filling the absorbent liquid up to the height position of the nozzle, and applying a vacuum pressure in the direction of the outlet of the scrubber housing to form a vortex of the absorbent liquid and gas inside the scrubber housing, thereby improving the scrubbing effect. will be.

Hereinafter, with reference to the accompanying drawings to be described in detail for the vortex-type gas-liquid mixed scrubber device according to an embodiment of the present invention.

1 is a schematic cross-sectional view of a vortex-type gas-liquid mixed scrubber device 10 using a vacuum pressure according to an embodiment of the present invention.

As shown in FIG. 1, the vortex-type gas-liquid mixing scrubber device 10 using the vacuum pressure according to the present invention is largely a scrubber housing 100, a gas-liquid vortex mixing unit 200, a mist removing unit, and a vacuum pump. And 400.

The scrubber housing 100, the gas inlet 110 is formed on the side surface of the housing, the gas discharge portion 120 is formed on the upper surface, the inner space of the cylindrical shape filled with the absorbent liquid to a predetermined height. Have

In addition, the gas-liquid vortex mixing unit 200 is provided in the scrubber housing 100, and the gas flowing from the gas inlet 110 is mixed with the absorbent liquid to form a vortex, which will be described below. This will be explained in detail.

In addition, the mist removal unit is located in the upper direction of the gas-liquid vortex mixing unit 200 in the scrubber housing 100, and serves to absorb the mist in the gas passing through the gas-liquid vortex mixing unit 200, scrubber Finally, the mist in the gas is finally removed before the gas is discharged to the outside of the device 10.

In addition, the vacuum pump 400 is provided in the direction of the gas discharge unit 120 of the scrubber housing 100 to apply a vacuum pressure to the inside of the scrubber housing 100, thereby the inside of the gas-liquid vortex mixing unit 200 It lowers the pressure, increases the speed of gas movement, increases the bubbling effect by the vortex in the gas-liquid vortex mixing unit 200, and consequently serves to improve the gas-liquid mixing rate.

The vacuum pressure that the vacuum pump 400 hangs inside the scrubber housing 100 is 250 to 400 mmAq, and preferably 300 to 350 mmAq.

In addition, in addition to the above-described configuration, the vortex type gas-liquid mixing scrubber device 10 using the vacuum pressure according to the present invention additionally includes a water level controller for adjusting the level of the absorbent liquid according to the filling height of the absorbent liquid or a heater for heating the inner absorbent liquid. can do.

On the other hand, the gas-liquid vortex mixing unit 200 is a combination of the impingement plate and the nozzle, as a configuration for contacting the gas flowing from the gas inlet 110 and the absorbent liquid filled in the scrubber housing 100, The first horizontal collision plate 210, the first vertical collision plate 220, the first nozzle 221, the second vertical collision plate 230, the second nozzle 231, the third vertical collision plate 240, The second horizontal collision plate 270, the first inclined collision plate 250, and the second inclined collision plate 260 are configured to be included.

First, the structure of each configuration of the gas-liquid vortex mixing unit 200 will be described in detail as follows.

The first horizontal collision plate 210 extends in a horizontal direction from an inner surface of the scrubber housing 100 in a direction in which the gas inlet 110 is formed at a position higher than the gas inlet 110. It consists of.

In addition, the first vertical collision plate 220 is installed in the vertical direction so as to be spaced apart and parallel to the inner surface of the scrubber housing 100, the gas inlet 110 is formed at a predetermined interval, the lower end is The lower surface of the scrubber housing 100 is spaced apart at a predetermined interval, the upper end is configured to be connected to the first horizontal impact plate 210.

In addition, the first nozzle 221 is formed in the first vertical impingement plate 220, and has an opening shape which protrudes in the lateral direction opposite to the side where the gas inlet is located, the opening being the filling height of the absorbent liquid. It is formed at a height adjacent to, and more preferably, the upper end of the opening is formed to match the filling height of the absorbent liquid.

As described above, since the upper end portion of the opening of the first nozzle 221 is formed in accordance with the filling height of the absorbent liquid, the vortex can be effectively formed on the surface of the absorbent liquid by the gas passing through the first nozzle 221.

In addition, the first nozzle 221 may further improve the vortex forming effect on the water surface of the absorbent liquid by configuring the first nozzle 221 horizontally on the lower surface of the scrubber housing at an angle of 180 degrees with respect to the water surface of the absorbent liquid.

In addition, the second vertical collision plate 230 is installed in the vertical direction so as to be spaced apart at predetermined intervals in parallel to the side surface direction opposite to the side where the gas inlet is located in the first vertical collision plate 220, the lower end Is spaced apart from the lower surface of the scrubber housing 100 at a predetermined interval, and the upper end is configured to be connected to the first horizontal collision plate 210.

In addition, the second nozzle 231 is formed in the second vertical collision plate 230 and has an opening shape protruding in a lateral direction opposite to the side where the first vertical collision plate 220 is located. Is formed at a height adjacent to the filling height of the absorbent liquid, and more preferably, the lower end of the opening is formed to match the filling height of the absorbent liquid.

Unlike the first nozzle 221 which is slightly submerged in the surface of the absorbent liquid as described above, the second nozzle 231 is formed at the lower end of the opening in accordance with the filling height of the absorbent liquid. Since the height of the surface of the absorbent liquid is not constant and the water level rises slightly due to the bubbling caused by the bubbling by the bubbling, the vortex can be formed more effectively than the position of the first nozzle 221 in order to effectively form the vortex on the surface portion of the absorbed liquid which is not fixed. It is preferable to slightly raise the position of the second nozzle 231.

In addition, the second nozzle 231 may further improve the vortex forming effect on the water surface of the absorbent liquid by configuring the second nozzle 231 horizontally on the lower surface of the scrubber housing at an angle of 180 degrees with respect to the water surface of the absorbent liquid.

On the other hand, the gas inlet flow rate of the gas inlet 110 is 6,000 to 6,000 to effectively discharge the gas through the first nozzle 221 and the second nozzle 231 to form the vortex and bubbling of the absorbent liquid At 12,000 m ³ / hr, the diameter of the opening of the first nozzle 221 or the second nozzle 231 is 8 to 10 mm.

For reference, the above-described adjacent height refers to a height in which the lower end of the opening of the first nozzle or the second nozzle is equal to or lower than the filling height of the absorbent liquid.

In addition, the third vertical collision plate 240 is installed in the vertical direction so as to be spaced apart and parallel to the second vertical collision plate 230 at a predetermined interval, the lower end of the absorption height of the absorbent liquid at a predetermined interval Spaced apart, the predetermined length is inclined toward the second collision plate direction at a predetermined angle from the lower end, the upper end is configured to be connected to the end of the first horizontal impact plate 210.

In this case, the third vertical collision plate 240 has a predetermined length from the lower end of the second collision plate at an angle (180 degrees -θ1) of 60 degrees or more and less than 90 degrees with respect to the surface of the absorbent liquid. By inclining the structure, the effect of separating the absorbing liquid mist and particles from the gas discharged from the gas-liquid vortex mixing unit 200 can be further enhanced.

In addition, the first inclined collision plate 250 is positioned between the first vertical collision plate 220 and the second vertical collision plate 230 and collides with the first vertical collision plate 220 and the second vertical collision plate. The plate 230 is spaced apart at predetermined intervals and installed in the vertical direction.

An upper end of the first inclined collision plate 250 is spaced apart from the first horizontal collision plate 210 at a predetermined interval, and a lower end is spaced apart from the lower surface of the scrubber housing 100 at a predetermined interval, Each of the upper and lower portions has a shape inclined toward the first vertical collision plate 220 at a predetermined angle, and the upper and lower boundaries have a height position adjacent to the height of the first nozzle 221. Preferably, it is configured to have a lower end height position of the first nozzle 221.

In this case, the first inclined collision plate 250 has a shape inclined toward the first vertical collision plate 220 at an angle θ2 of 70 to 80 degrees based on a boundary between an upper portion and a lower portion. The lower portion has an inclined shape in the direction of the first vertical collision plate 220 at an angle of 180 to 70 degrees.

The lower portion of the first inclined collision plate 250 is inclined in the direction of the first vertical collision plate 220 at the same angle as described above, so that the gas discharged from the first nozzle 221 is first inclined collision plate ( It may be prevented from passing in the direction of the second vertical collision plate 230 at the lower portion of the 250.

In addition, the upper portion of the first inclined collision plate 250 is inclined in the direction of the first vertical collision plate 220 at the same angle as described above, so that the gas discharged from the first nozzle 221 is inclined Ascending between the impingement plate 250 and the first vertical impingement plate 220 may collide with the first inclined impingement plate 250 to maximize the separation effect of the absorbent liquid mist and particles in the gas.

In addition, the second inclined collision plate 260 is positioned between the second vertical collision plate 230 and the third vertical collision plate 240 to collide with the second vertical collision plate 230 and the third vertical collision plate 230. The plate 240 is spaced at a predetermined interval and installed in the vertical direction.

The upper end of the second inclined collision plate 260 is spaced apart from the first horizontal collision plate 210 at a predetermined interval, and the lower end is spaced apart from the lower surface of the scrubber housing 100 at a predetermined interval, Each of the upper and lower portions has a shape inclined toward the second vertical collision plate 230 at a predetermined angle, and the boundary between the upper and lower portions has a height position adjacent to the height of the second nozzle 231. Preferably, it is configured to have a lower end height position of the second nozzle 231.

In this case, the second inclined collision plate 260 has a shape inclined toward the second vertical collision plate 230 at an angle θ4 of 70 to 80 degrees based on a boundary between an upper portion and a lower portion. The lower portion has an inclined shape in the direction of the second vertical collision plate 230 at an angle of 180 to θ5 of 60 to 70 degrees.

The lower portion of the second inclined collision plate 260 is inclined in the direction of the second vertical collision plate 230 at the same angle as described above, so that the gas discharged from the second nozzle 231 is discharged to the second inclined collision plate ( It may be prevented from passing in the direction of the third vertical collision plate 240 from the lower portion of the 260.

In addition, the upper portion of the second inclined collision plate 260 is inclined in the direction of the second vertical collision plate at the same angle as described above, so that the gas discharged from the second nozzle 231 is discharged to the second inclined collision plate ( Ascending between the 260 and the second vertical impingement plate 230 may collide with the second inclined impingement plate 260 to maximize the separation effect of the absorbent mist and particles in the gas.

On the other hand, the first inclined collision plate 250 or the second inclined collision plate 260 may be configured such that the angle between the upper and lower boundary portions respectively has an obtuse angle. As described above, when the oblique impact plate is formed at an obtuse angle, the effect of the absorbent liquid being scattered in the air while rotating on the plane of the inclined collision plate is increased. When is improved, the scattered absorbent liquid is further combined with the particles in the gas rising while descending to amplify the effect of separating the particles in the gas.

In addition, the second horizontal collision plate 270 has an inner surface of the scrubber housing 100 in a direction in which the first horizontal collision plate 210 is not formed at a position higher than the first horizontal collision plate 210. It has a form extending in the transverse direction from, the predetermined length from the extended end is configured to be inclined toward the lower direction at a predetermined angle.

The second horizontal impingement plate 270 has a predetermined length from the extended end so as to be inclined through the bent portion in the downward direction over the secondary, and the inner angle of the bent portion has an angle of 120 to 160 degrees, Mist and particles in the gas are finally separated from the gas discharged from the gas-liquid vortex mixing unit 200.

In addition, the vortex-type gas-liquid mixed scrubber device 10 using the vacuum pressure according to another embodiment of the present invention, as shown in Figure 2, the first vortex amplifying plate 280 and the second vortex amplifying plate ( 290) can be configured to include.

The vortex amplifying plates eject the absorbent liquid moving in the direction of each inclined collision plate by the gas discharged from the nozzle upward through a flow path formed between the inclined collision plate and the vortex amplification plate, thereby primarily vortexing the absorbent liquid. And it is possible to maximize the bubbling effect, and secondly to maximize the particle separation effect in the gas according to the absorbing liquid injection effect by the absorbing liquid is blown into the air.

To this end, the first vortex amplifying plate 280 is located between the first inclined collision plate 250 and the first vertical collision plate 220, and the first inclined collision plate 250 and a predetermined Spaced adjacent to each other, the upper part of which extends in a predetermined length in parallel with the first inclined crash plate 250 and the lower part is concavely rounded toward the first vertical crash plate 220. It is composed.

In addition, the second vortex amplifying plate 290 is positioned between the second inclined collision plate 260 and the second vertical collision plate 230, and is spaced a predetermined distance from the second inclined collision plate 260. Spaced apart adjacent to each other, the upper portion extends in a predetermined length in parallel with the second inclined collision plate 260 and the lower portion is concave round in the direction of the second vertical collision plate 230. do.

As described above, the structure of the vortex amplifying plate has a form in which the lower part has a rounded shape, and the upper part has a narrow flow path parallel to the inclined impingement plate, so that the absorbent liquid pushed into the lower part of the vortex amplifying plate and the inclined impingement plate has a low pressure Since it is ejected on the surface of the absorbent liquid at a high speed, it is possible to maximize the vortex and bubbling effect of the absorbent liquid and the absorbing liquid spraying effect.

Figure 3 shows the flow of gas in the vortex type gas-liquid mixed scrubber device 10 using the vacuum pressure according to the present invention.

As shown in FIG. 3, the gas introduced into the gas inlet 110 hits the first inclined collision plate 250 and the first horizontal collision plate 210 and is filled with the scrubber housing 100 filled with the absorbent liquid. It descends in the direction, and passes through the first vertical collision plate 220 through the first nozzle 221 formed in the lower portion of the first vertical collision plate 220.

At this time, while the gas passes through the first nozzle 221, the vortex is first formed on the surface of the absorbent liquid to mix the absorbent liquid and the gas. At this time, as the absorbent liquid is rotated together with the gas, contaminants are absorbed and removed by the absorbent liquid, and the purified gas rises upward.

Gas passing through the first nozzle 221 rises in the upper direction of the scrubber housing 100 while colliding with the first inclined collision plate 250, and the elevated gas collides with the first horizontal collision plate 210 again to the second vertical. A second vertical impingement descends downward along the impingement liquid 230 along the impingement plate 230 and through a second nozzle 231 formed under the second vertical impingement plate 230. Pass through plate 230.

At this time, while the gas passes through the second nozzle 231, the vortex is secondarily formed on the surface of the absorbent liquid to further improve the mixing ratio between the absorbent liquid and the gas. At this time, as the absorbent liquid is rotated together with the gas, contaminants are absorbed and removed by the absorbent liquid, and the purified gas rises upward.

The gas passing through the second nozzle 231 hits the second inclined collision plate 260 and rises upward in the upper direction of the scrubber housing 100, and the gas rises again with one side surface of the first horizontal collision plate 210. While falling, the lower portion of the scrubber housing 100 is lowered along the third vertical collision plate 240. At this time, while the gas hits the bent end of the third vertical collision plate 240, the absorbent liquid particles in the gas are dropped.

As such, the gas lowered by hitting the third vertical collision plate 240 rises in the upper direction of the scrubber housing 100 along the wall surface of the scrubber housing 100 and the other side surface of the third vertical collision portion. While absorbing the second horizontal collision part, the absorbent liquid particles in the gas are dropped again.

The gas that collides with the second horizontal impingement portion passes through the space between the second horizontal impingement portion and the first horizontal impingement portion and ascends upwardly of the scrubber housing 100, and finally removes the absorbent liquid particles in the gas while passing through the mist removing part. do.

The gas passing through the mist removing unit is discharged to the outside of the scrubber housing 100 through the gas discharge unit 120.

The present invention has been described above with reference to the embodiments illustrated in the accompanying drawings, which are merely exemplary, and various modifications and equivalent other embodiments may be made by those skilled in the art to which the present invention pertains. Will understand. Therefore, the technical protection scope of the present invention will be defined by the claims below.

10: Vortex type gas-liquid mixing scrubber device using vacuum pressure
100: scrubber housing
110: gas inlet
120: gas outlet
200: gas-liquid vortex mixing unit
210: first horizontal collision plate
220: first vertical collision plate
221: first nozzle
230: second vertical collision plate
231: second nozzle
240: third vertical collision plate
250: first inclined collision plate
260: second inclined collision plate
270: second horizontal collision plate
280: first vortex amplifying plate
290: second vortex amplifying plate
300: Mist Eliminator
400: vacuum pump

Claims (13)

A scrubber housing having a cylindrical inner space in which a gas inlet is formed at a side portion, a gas discharge portion is formed at an upper surface, and an absorbent liquid is filled at a predetermined height;
A gas-liquid vortex mixing unit which is provided inside the scrubber housing and in which the gas flowing from the gas inlet unit forms a vortex with the absorbent liquid and is mixed;
A mist removal unit positioned in an upper direction of the gas-liquid vortex mixing unit in the scrubber housing and absorbing mist in the gas passing through the gas-liquid vortex mixing unit; And
In the vortex-type gas-liquid mixed scrubber device using a vacuum pressure comprising a; vacuum pump provided in the direction of the gas discharge portion of the scrubber housing to apply a vacuum pressure inside the scrubber housing,
The gas-liquid vortex mixing unit,
A first horizontal collision plate configured to extend in a horizontal direction from an inner side surface of the scrubber housing in a direction in which the gas inlet is formed at a position higher than the gas inlet;
It is installed in a vertical direction so as to be spaced apart and parallel to the inner surface of the scrubber housing in which the gas inlet is formed, the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, the upper end is the first A first vertical collision plate configured to be connected to the horizontal collision plate;
A first nozzle formed in the first vertical impingement plate and having an opening shape protruding in a lateral direction opposite to a side at which the gas inlet is located, the opening being formed at a height adjacent to the filling height of the absorbent liquid;
The first vertical collision plate is installed in the vertical direction so as to be spaced apart at a predetermined interval in parallel to the side of the side opposite the side where the gas inlet is located, the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, A second vertical impingement plate configured to have a distal end connected to the first horizontal impingement plate;
A second nozzle formed in the second vertical impingement plate and having an opening shape protruding in a lateral direction opposite to a side at which the first vertical impingement plate is located, the opening being formed at a height adjacent to the filling height of the absorbent liquid;
It is installed in the vertical direction so as to be spaced apart and parallel to the second vertical collision plate at a predetermined interval, and the lower end is spaced at a predetermined interval from the filling height of the absorbent liquid, the predetermined length from the lower end at a predetermined angle A third vertical collision plate having a shape inclined toward a second vertical collision plate, and having an upper end connected to an end of the first horizontal collision plate;
Located between the first vertical collision plate and the second vertical collision plate, spaced apart from the first vertical collision plate and the second vertical collision plate at a predetermined interval and installed in the vertical direction, the upper end is the first horizontal collision Spaced apart from the plate at a predetermined interval, and the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, and the upper and lower portions each have an inclined shape in the direction of the first vertical collision plate at a predetermined angle. A first inclined collision plate configured to have a height position adjacent to a bottom of the first nozzle;
Located between the second vertical collision plate and the third vertical collision plate, spaced apart from the second vertical collision plate and the third vertical collision plate at a predetermined interval and installed in the vertical direction, the upper end is the first horizontal collision Spaced apart from the plate at a predetermined interval, and the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, and the upper and lower portions each have an inclined shape in the direction of the second vertical collision plate at a predetermined angle. A second inclined impingement plate configured to have a height position adjacent to a height of the second nozzle;
At a position higher than the first horizontal impact plate, the first horizontal impact plate has a shape extending in a horizontal direction from an inner surface of the scrubber housing in a direction in which the first horizontal impact plate is not formed, and a predetermined length from the extended end is lowered at a predetermined angle. A second horizontal collision plate configured to be inclined in a direction; And
Located between the first inclined collision plate and the first vertical collision plate, spaced adjacent to the first inclined collision plate at a predetermined interval, the upper portion relative to the center of the predetermined in parallel with the first inclined collision plate Vortex-type gas-liquid mixing scrubber device using a vacuum pressure, characterized in that it comprises; a first vortex amplifying plate extending in the length of the lower portion is formed concave round in the direction of the first vertical impingement plate. A scrubber housing having a cylindrical inner space in which a gas inlet is formed at a side portion, a gas discharge portion is formed at an upper surface, and an absorbent liquid is filled at a predetermined height;
A gas-liquid vortex mixing unit which is provided inside the scrubber housing and in which the gas flowing from the gas inlet unit forms a vortex with the absorbent liquid and is mixed;
A mist removal unit positioned in an upper direction of the gas-liquid vortex mixing unit in the scrubber housing and absorbing mist in the gas passing through the gas-liquid vortex mixing unit; And
In the vortex-type gas-liquid mixed scrubber device using a vacuum pressure comprising a; vacuum pump provided in the direction of the gas discharge portion of the scrubber housing to apply a vacuum pressure inside the scrubber housing,
The gas-liquid vortex mixing unit,
A first horizontal collision plate configured to extend in a horizontal direction from an inner side surface of the scrubber housing in a direction in which the gas inlet is formed at a position higher than the gas inlet;
It is installed in a vertical direction so as to be spaced apart and parallel to the inner surface of the scrubber housing in which the gas inlet is formed, the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, the upper end is the first A first vertical collision plate configured to be connected to the horizontal collision plate;
A first nozzle formed in the first vertical impingement plate and having an opening shape protruding in a lateral direction opposite to a side at which the gas inlet is located, the opening being formed at a height adjacent to the filling height of the absorbent liquid;
The first vertical collision plate is installed in the vertical direction so as to be spaced apart at a predetermined interval in parallel to the side of the side opposite the side where the gas inlet is located, the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, A second vertical impingement plate configured to have a distal end connected to the first horizontal impingement plate;
A second nozzle formed in the second vertical impingement plate and having an opening shape protruding in a lateral direction opposite to a side at which the first vertical impingement plate is located, the opening being formed at a height adjacent to the filling height of the absorbent liquid;
It is installed in the vertical direction so as to be spaced apart and parallel to the second vertical collision plate at a predetermined interval, and the lower end is spaced at a predetermined interval from the filling height of the absorbent liquid, the predetermined length from the lower end at a predetermined angle A third vertical collision plate having a shape inclined toward a second vertical collision plate, and having an upper end connected to an end of the first horizontal collision plate;
Located between the first vertical collision plate and the second vertical collision plate, spaced apart from the first vertical collision plate and the second vertical collision plate at a predetermined interval and installed in the vertical direction, the upper end is the first horizontal collision Spaced apart from the plate at a predetermined interval, and the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, and the upper and lower portions each have an inclined shape in the direction of the first vertical collision plate at a predetermined angle. A first inclined collision plate configured to have a height position adjacent to a bottom of the first nozzle;
Located between the second vertical collision plate and the third vertical collision plate, spaced apart from the second vertical collision plate and the third vertical collision plate at a predetermined interval and installed in the vertical direction, the upper end is the first horizontal collision Spaced apart from the plate at a predetermined interval, and the lower end is spaced apart from the lower surface of the scrubber housing at a predetermined interval, and the upper and lower portions each have an inclined shape in the direction of the second vertical collision plate at a predetermined angle. A second inclined impingement plate configured to have a height position adjacent to a height of the second nozzle;
At a position higher than the first horizontal impact plate, the first horizontal impact plate has a shape extending in a horizontal direction from an inner surface of the scrubber housing in a direction in which the first horizontal impact plate is not formed, and a predetermined length from the extended end is lowered at a predetermined angle. A second horizontal collision plate configured to be inclined in a direction; And
Located between the second inclined collision plate and the second vertical collision plate, spaced adjacent to the second inclined collision plate at a predetermined interval, the upper portion relative to the center of the predetermined predetermined parallel to the second inclined collision plate Vortex type gas-liquid mixing scrubber device using a vacuum pressure, characterized in that it comprises; a second vortex amplifying plate extending in the length of the lower portion is formed concave round in the direction of the second vertical impingement plate. The method according to claim 1 or 2,
Vortex type gas-liquid mixing scrubber device using a vacuum pressure, comprising: a water level controller for adjusting the level of the absorbent liquid in accordance with the filling height of the absorbent liquid. The method according to claim 1 or 2,
The scrubber housing,
A vortex-type gas-liquid mixed scrubber device using a vacuum pressure, characterized in that it comprises a heater for heating the internal absorption liquid. The method according to claim 1 or 2,
The first inclined collision plate,
On the basis of the boundary between the upper and lower, the upper portion has a form inclined in the direction of the first vertical collision plate at an angle of 70 to 80 degrees, the lower portion inclined in the direction of the first vertical collision plate at an angle of 60 to 70 degrees Vortex type gas-liquid mixing scrubber apparatus using a vacuum pressure, characterized in that it has a form. The method according to claim 1 or 2,
The second inclined collision plate,
Based on a boundary between an upper and a lower portion, the upper portion is inclined toward the second vertical collision plate at an angle of 70 to 80 degrees, and the lower portion is inclined toward the second vertical collision plate at an angle of 60 to 70 degrees. Vortex type gas-liquid mixing scrubber apparatus using a vacuum pressure, characterized in that it has a form. The method according to claim 1 or 2,
The first inclined collision plate or the second inclined collision plate,
A vortex-type gas-liquid mixing scrubber device using a vacuum pressure, characterized in that the angle between the upper and lower boundary portions has an obtuse angle. The method according to claim 1 or 2,
The opening of the first nozzle or the second nozzle,
Vortex-type gas-liquid mixed scrubber device using a vacuum pressure, characterized in that the horizontal configuration on the lower surface of the scrubber housing at an angle of 180 degrees relative to the water surface of the absorbent liquid. The method according to claim 1 or 2,
The third vertical collision plate,
Vortex type gas-liquid mixing scrubber device using a vacuum pressure, characterized in that the predetermined length from the lower end is inclined toward the second impingement plate at an angle of more than 60 degrees and less than 90 degrees relative to the water surface of the absorbent liquid. . The method according to claim 1 or 2,
The second horizontal collision plate,
A predetermined length from the extended end is inclined through the bent portion in a downward direction over the secondary, wherein the inner angle of the bent portion has an angle of 120 to 160 degrees, vortex type gas-liquid mixed type using vacuum pressure Scrubber device. The method according to claim 1 or 2,
The gas inlet,
The gas inlet flow ranges from 6,000 to 12,000 m ³ / hr,
The first nozzle or the second nozzle,
A vortex-type gas-liquid mixing scrubber device using a vacuum pressure, characterized in that the diameter of the opening is 8 to 10 mm. delete The method according to claim 1 or 2,
The vacuum pump,
Vortex type gas-liquid mixing scrubber device using a vacuum pressure, characterized in that to apply a vacuum pressure of 250 to 400mmAq inside the scrubber housing.

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